Ivar KJELBERG
COMSOL Multiphysics(r) fan, retired, former "Senior Expert" at CSEM SA (CH)
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Posted:
1 decade ago
2012年5月9日 GMT-4 02:16
Hi
I have noticed too that the non linear tick, tends to lower the load factor by 1 unit about, and that you can get negative "security factor".
As it's called "linear buckling" so turning on non-linear geoemtry is perhaps an assumption violation
I find this value of "1" quite puzzeling, why tend assymptotically to "1" ? this could also explain the negative values, when you go above the buckling limit, at least it makes some sens for a simple case of a vertical fixed free rod, comparing to standard buckling theory
I would expect a non-linear geometry simulation to give a lower security factor, and say that anything below +1 is critical and will self buckle
It's perhaps worth a question to support to get it explained once.
There is a similar question when adding some damping, how to consider the compelx results, take the abs() values ?
Sorry no reply here, just more questions ;)
--
Good luck
Ivar
Hi
I have noticed too that the non linear tick, tends to lower the load factor by 1 unit about, and that you can get negative "security factor".
As it's called "linear buckling" so turning on non-linear geoemtry is perhaps an assumption violation
I find this value of "1" quite puzzeling, why tend assymptotically to "1" ? this could also explain the negative values, when you go above the buckling limit, at least it makes some sens for a simple case of a vertical fixed free rod, comparing to standard buckling theory
I would expect a non-linear geometry simulation to give a lower security factor, and say that anything below +1 is critical and will self buckle
It's perhaps worth a question to support to get it explained once.
There is a similar question when adding some damping, how to consider the compelx results, take the abs() values ?
Sorry no reply here, just more questions ;)
--
Good luck
Ivar
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
2012年5月9日 GMT-4 05:16
Dear Ivar
Do you mean "security factor" is the same concept as "the critical load factor"?
I turn on nonlinear geoemtry in step 1 and step 2 (study 1).
I got the critical load factors in three load cases:
140 for load case 1(=Gd+Qd);
-98 for load case 2 (= load case 1+Fd1);
44 for load case 3 (= load case 2+Fd2).
The result (negative critical load factor) shows that the buckling occurs in the load case 2, right?
But when I continue to add a new load in the neighbour position with the same direction, the critical load factor becomes positive value, the structure "becomes" safe status!
Is anything below +1 critical and will self buckle?
The model is attached.
Thank for your reply!
-dazhuo
Dear Ivar
Do you mean "security factor" is the same concept as "the critical load factor"?
I turn on nonlinear geoemtry in step 1 and step 2 (study 1).
I got the critical load factors in three load cases:
140 for load case 1(=Gd+Qd);
-98 for load case 2 (= load case 1+Fd1);
44 for load case 3 (= load case 2+Fd2).
The result (negative critical load factor) shows that the buckling occurs in the load case 2, right?
But when I continue to add a new load in the neighbour position with the same direction, the critical load factor becomes positive value, the structure "becomes" safe status!
Is anything below +1 critical and will self buckle?
The model is attached.
Thank for your reply!
-dazhuo
Ivar KJELBERG
COMSOL Multiphysics(r) fan, retired, former "Senior Expert" at CSEM SA (CH)
Please login with a confirmed email address before reporting spam
Posted:
1 decade ago
2012年5月9日 GMT-4 09:18
Hi
Nice model, but I cannot really give you "the response" because I see we are stuck with the same issue.
What I can tell you and that I verified with the simple model hereby (its a 4.2a I do not have any older version up running), is that when you add self weight AND a force load, your "critical load factor" (= my security factor, sorry for the confusion) corresponds to a mix of BOTH loads, as these are cummulative.
So I would say start with only its proper weight under 1*G, get the load factor, which then corresponds to N*G. Then remove the body load and have a single force load and get the load factor per Newton (perhaps for forces applied at different places).
Then you need to do a good engineering guess how to combine both results into a fixed self weight part and an additional extra load part. These do not really add linearly, as the self weight is a globally distributed force, while the force load is generally a locally distributed load
And I would run it without the "non-linear geometry" to start with, then the behaviour at least is linear (doubling force means half the critical load factor
By the way a body load scales qith a (SF)^(1/3) law, a force with a linear law
--
Good luck
Ivar
Hi
Nice model, but I cannot really give you "the response" because I see we are stuck with the same issue.
What I can tell you and that I verified with the simple model hereby (its a 4.2a I do not have any older version up running), is that when you add self weight AND a force load, your "critical load factor" (= my security factor, sorry for the confusion) corresponds to a mix of BOTH loads, as these are cummulative.
So I would say start with only its proper weight under 1*G, get the load factor, which then corresponds to N*G. Then remove the body load and have a single force load and get the load factor per Newton (perhaps for forces applied at different places).
Then you need to do a good engineering guess how to combine both results into a fixed self weight part and an additional extra load part. These do not really add linearly, as the self weight is a globally distributed force, while the force load is generally a locally distributed load
And I would run it without the "non-linear geometry" to start with, then the behaviour at least is linear (doubling force means half the critical load factor
By the way a body load scales qith a (SF)^(1/3) law, a force with a linear law
--
Good luck
Ivar